Effects of Certain Inhibitors on Photorespiration by Wheat Leaf Segments

The effect on the carbon metabolism of wheat leaf segments ofcertain inhibitors of photorespiration was studied. Sodium 2-hydroxy-3-butynoatesupplied for 40 min resulted in accumulation of ¹⁴C in glycolicacid with only a 7% inhibition of photosynthesis; when suppliedfor 90 min, photosynthesis was inhibited by 47%. When ¹⁴CO₂was replaced by 1000 vpm ¹²CO₂, radioactivity in glycine decreasedbut increased more rapidly in sucrose with less release of ¹⁴CO₂.Isonicotinyl hydrazide (INH) inhibited photosynthesis from ¹⁴CO₂by 50% and glycine replaced sucrose as the main product. When,after 15 min, ¹⁴CO₂ was replaced by 150 vpm ¹²CO₂, in the presenceof INH less ¹⁴CO₂ was released, ¹⁴CO in glycine decreased moreslowly, and less [¹⁴CO]sucrose accumulated. Glycidate (potassium2,3-epoxypropionate) at 2 mM had no effect on photosyntheticrate and little effect on carbon metabolism; 20 mM glycidateinhibited photosynthesis by 64% and resulted in less radioactivityin glycine, more in phosphate esters, and less ¹⁴CO₂ released.When photosynthesis was measured in 1000 vpm CO₂ the inhibitorsgave smaller effects on metabolism than during photosynthesisfrom 150 vpm ¹⁴CO₂ but 20 mM glycidate still resulted in a 42%inhibition of photosynthesis. When U- [¹⁴CO]glycerate was appliedto leaf segments in air with 320 vpm ¹⁴CO₂ the total uptakeof glycerate was not changed by the inhibitors. INH and glycidateboth decreased the amount of glycerate metabolised. More ¹⁴COaccumulated in glycine in the presence of INH and in phosphateesters and serine in the presence of glycidate. Hydroxybutynoateincreased the production of glycolate from glycerate but didnot affect the total amount of glycerate metabolised. Although all three inhibitors affected photorespiratory metabolismnone stimulated photosynthesis. The results are consistent withthe main release of CO₂ in photorespiration arising from theconversion of glycine to serine.     

Effect of Oxygen on Photosynthetic 14CO2 Fixation in Chroomonas sp. (Cryptophyta) III: Effect of Oxygen on Photosynthetic Carbon Metabolism

Photosynthetic carbon metabolism was studied with Chroomonassp. cells in which the rate of photosynthesis was inhibitedunder both an anaerobic condition and high concentrations ofoxygen. The time course of ¹⁴C-incorporation into photosyntheticproducts showed that 3-phosphoglycerate was the initial productof photosynthetic CO₂ fixation in Chroomonas sp. cells. During5-min photosynthesis, a considerable amount of ¹⁴C was incorporatedinto the insoluble fraction (mostly cryptomonad starch), andoxygen predominantly affected ¹⁴C-incorporation into this fraction.Although ¹⁴C-incorporation into intermediates of the photorespiratorypathway increased with increasing O₂ concentration, the amountswere much less than expected from the degree of oxygen inhibition.It is noteworthy that ¹⁴C-dihydroxyacetone phosphate accumulatedduring photosynthesis only under the anaerobic condition, whereasthe levels of the other phosphate esters were scarcely affectedby the oxygen concentration. Ribulose-1,5-bisphosphate carboxylase from Chroomonas sp. wascompetitively inhibited by oxygen, and its K_m(CO₂) value wassimilar to those of terrestrial C₃ plant enzymes. (Received November 19, 1984; Accepted May 20, 1985)     

Phytotoxicity of Phthalate Plasticisers: 2. SITE AND MODE OF ACTION

The effects of phthalate esters on chlorophyll a₂ fluorescencein radish plants (Raphanus sativus L. cv. Cherry Belle) wereexamined Fluorescence yield was increased in those plants exposedto an aerial concentration of 120 ng dm^–3 dibutyl phthaiatc(DBP) at a rate of 3.0 dm³ min^–1 for 13 d. Comparisonof fluorescence enhancement ratios and F_red/F_ox, suggests thatDBP inhibits photosynthesis in radish plants at a site afterQ_A. Both DBP and diisobutyl phthalate (DIBP) strongly inhibiteduncoupled (PS2+PS1) electron transport rates in thylakoids isolatedfrom spinach. At a chlorophyll concentration of 10 µgcm^–3 the concentrations of DBP and DIBP exhibiting 50%inhibition were 44 mmol m^–3 and 42 mmol m^–3 respectively.Basal electron transport rates were also inhibited, with 87mmol m^–3 of DBP or DIBP producing 50% inhibition. Measurementof photosystcm 1 activity suggested that the main site of actionof these phthalates was localized at a site near the reducingside of photosystem 2. Key words: Phthalate, plasticiser, chlorophyll, fluorescence, photosynthesis, inhibition     

Bisulfite compounds as metabolic inhibitors: nonspecific effects on membranes

Bisulfite compounds are shown to be nonspecific inhibitors ofphotosynthetic processes and of ion transport in green tissues.CO₂ fixation and light-dependent transient changes in externalpH are inhibited about 50% by 5x10^–4 M glyoxal-Na-bisulfite.Chloride uptake in the light and in the dark is inhibited tothe same extent at this concentration. At 5x10^–3 M theinhibitor reduces ATP levels in the light and in the dark, andeffects on glycolate oxidase and PEP carboxylase are observed.The extent of inhibition is dependent on time of treatment withglyoxal-Na-bisulfite and freshly prepared NaHSO₃ is equallyas effective as the addition compound. Possible explanations of the bisulfite effects and the relationshipsto SO₂ effects on photosynthesis are discussed. (Received September 1, 1971; )     

Effect of L-Methionine Sulphoximine on the Products of Photosynthesis in Wheat (Triticum aestivum) Leaves

Methionine sulphoximine, an inhibitor of glutamine synthetase,caused ammonia accumulation in detached wheat leaves. The ratewas increased by increased oxygen in the atmosphere and by simultaneouslysupplying glycine or giving extra nitrate; it was decreasedby isonicotinyl hydrazide. Ammonia production was light-dependentand continued at a constant rate in air for at least 2 h. Photosynthesiswas progressively inhibited after the first hour; this inhibitionwas not because of increased stomatal resistance. Leaves suppliedwith 30 mol m^–3 ammonium chloride, without methioninesulphoximine, accumulated more ammonia than leaves treated withthe inhibitor but showed less inhibition of photosynthesis.The inhibitor decreased synthesis of [¹⁴C] amino acids from¹⁴CO₂ in the light but increased the synthesis of [¹⁴C] malateand, relatively, the incorporation of ¹⁴C into sugar phosphates.In the absence of inhibitor, nitrate increased and ammoniumion decreased synthesis of malate. Methionine sulphoximine,by causing a shortage of amino acids, probably inhibited photosynthesisin part by decreasing the recycling of carbon from the photorespiratorycycle back to the Calvin cycle. Key words: Photosynthetic ¹⁴CO₂ assimilation, Methionine sulphoximine, Detached wheat leaves     

Glyoxylate Inhibition of Ribulosebisphosphate Carboxylase/Oxygenase Activation State in vivo

Photosynthetic CO₂ exchange in photorespiration mutants of Arabidopsisthaliana showed a time-dependent inhibition at 350 µl/literCO₂ in 50% O₂ but not in 2% O₂. In a glycolate-P phos-phatasedeficient mutant, inhibition of photosynthesis was due to adepletion of ribulosebisphosphate. In the remaining mutants,which have defects in photorespiratory enzymes which metabolizeamino acids, reduced photosynthesis was accompanied by a declinein the activation level of ribulosebisphosphate carboxylase/oxygenase(Chastain and Ogren 1985), a decline in ribulosebisphosphateconcentration, and an accumulation of glyoxylate. Addition ofglyoxylate at submillimolar concentrations to intact spinach(Spinacea oleracea L.) chloroplasts inhibited light activationof ribulosebisphosphate carboxylase/oxygenase (rubisco) andCO₂ fixation. Similar concentrations of glyoxylate had no effecton A. thaliana rubisco activity in vitro. These results suggestthat glyoxylate accumulation indirectly inhibited rubisco activationstate in vivo. The inhibition of photosynthesis in mutants whichaccumulate glyoxylate may be attributed to a decline in ribulosebisphosphateconcentration, a reduction in rubisco activation state, or acombination of both phenomena. ³Present address: CSIRO, Division of Plant Industry, GPO Box1600, Canberra, ACT 2601, Australia. (Received May 12, 1989; Accepted July 8, 1989)     

Rates of Photosynthesis in Characean Cells: I. PHOTOSYNTHETIC 14CO2 FIXATION BY NITELLA TRANSLUCENS

A study has been made of photosynthetic ¹⁴CO₂ fixation by isolated‘mature’ internodes of Nitella translucens. Experimentalconditions were similar to those used in studies of the ionicrelations of these cells. Maximum rates of photosynthesis were33–40µµmoles CO₂, fixed per cm² of surfacearea per second (equivalent to 12–15 /xmoles fixed permg chlorophyll per hour). ^l4CO₂ fixation was inhibited to thedark level by 3(3,4,dichlorophenyl)-1, 1-dimethylurea (at 0-6µM or 10µM) and by the uncoupler carbonyl cyanide-m-chlorophenylhydrazone(SµM). The presence of imidazole or ammonium sulphate(both of which uncouple ATP production in vitro) did not resultin an inhibition of 14CO2 fixation. These results are discussedin relation to published work on solute uptake by Nitella translucens.During photosynthesis there was rapid movement of ¹⁴C-labelledorganic compounds out of the chloroplasts. ¹⁴C-labelled sucrose,ammo-acids, and sugar phosphates were found in samples of vacuolarsap.     

Effect of Methionine Sulfoximine on Photosynthetic Carbon Metabolism in Wheat Leaves

Methionine sulfoximine (MSO) greatly reduced the carbon dioxideexchange rate (CER) of detached wheat (Triticum aestivvm L.cv Roland) leaves in 21% O₂, but only slightly reduced it in2% O₂. A supply of 50 mM NH₄Cl had little effect on the CERirrespective of the O₂ concentration. A simultaneous additionof glutamine and MSO protected against the inhibition of photosynthesisto a considerable extent and caused the accumulation of moreNH₃ than did the addition of MSO alone. Fixation of ¹⁴CO₂ in wheat leaves was inhibited by MSO treatmentin 22% O₂, and there was decreased incorporation of ¹⁴G intoamino acids and sugars and increased label into acid fractions.The addition of MSO and glutamine together eliminated the effectof MSO on the photosynthetic ¹⁴CO₂ fixation pattern. NH₄Cl stimulatedthe synthesis of amino acids from ¹⁴CO₂, especially the synthesisof serine in 22% O₂. Our observations show that factors other than the uncouplingof photophosphorylation by accumulated NH₃ may be responsiblefor the early stage of photosynthesis inhibition by MSO underphotorespiratory conditions. ¹Present address: Department of Agricultural Chemistry, KyushuUniversity, Fukuoka 812 Japan. ²Also at U.S. Department of Agriculture, Agricultural ResearchService, Urbana, Illionois 61801, U.S.A. (Received September 13, 1983; Accepted February 2, 1984)     

Effect of linolenate on photosynthesis by intact spinach chloroplasts II. Influence of preillumination of leaves on the inhibition of photosynthesis by linolenate

The inhibitory effect of linolenate on intact spinach chloroplastsdepends on the level of the internal pool of metabolites. Chloroplastsfrom preilluminated leaves or chloroplasts artificially loadedwith 3-phosphoglyceric acid required higher concentrations oforthophosphate for maximal rates of CO₂ dependent O₂ evolutionthan untreated chloroplasts. The loaded chloroplasts were moresensitive to linolenate, and in the presence of linolenate theoptimal phosphate concentration was shifted toward lower values.We propose that the inhibition of photosynthesis by linolenateis due to inhibition of the "phosphate translocator". ¹ Part of this work has been published in the Book of Abstracts,4th International Congress on Photosynthesis, Reading, U.K.,1977, p. 265–266. ² This work is part of a doctoral programme carried out by L.Mv6 Akamba in this laboratory. ³ To whom reprint requests should be adressed. (Received October 14, 1978; )     

Effects of Nitrogen Nutrition on Photosynthesis in Cd-treated Sunflower Plants

Increased nitrogen supply stimulates plant growth and photosynthesis.Since it was shown that heavy metals may cause deficienciesof essential nutrients in plants the potential reversal of cadmiumtoxicity by increased N nutrition was investigated. The effectson photosynthesis of low Cd (0, 0.5, 2 or 5 mmol m^-3) combinedwith three N treatments (2, 7.5 or 10 mol m^-3) were examinedin young sunflower plants. Chlorophyll fluorescence quenchingparameters were determined at ambient CO₂and at 100 or 800 µmolquanta m^-2 s^-1. The vitality index (R_fd) decreased approx. three-timesin response to 5 mmol m^-3Cd, at 2 and 10 mol m^-3N. The maximumphotochemical efficiency of PSII reaction centres (F_v/ F_m) wasnot influenced by Cd or N treatment. The highest Cd concentrationdecreased quantum efficiency of PSII electron transport (_II)by 30%, at 2 and 10 mol m^-3N, mostly due to increased closureof PSII reaction centres (q_P). Photosynthetic oxygen evolutionrates at saturating CO₂were decreased in plants treated with5 mmol m^-3Cd, at all N concentrations. The results indicatethat Cd treatment affected the ribulose-1,5-bisphosphate (RuBP)regeneration capacity of the Calvin cycle more than other processes.At the same time, the amounts of soluble and ribulose-1,5-bisphosphatecarboxylase/oxygenase (Rubisco) protein increased with Cd treatment.Decreased photosynthesis, but substantially increased Rubiscocontent, in sunflower leaves under Cd stress indicate that asignificant amount of Rubisco protein is not active in photosynthesisand could have another function. It is shown that optimal nitrogennutrition decreases the inhibitory effects of Cd in young sunflowerplants. Copyright 2000 Annals of Botany Company Helianthus annuus L., cadmium, nitrogen, photosynthesis, Rubisco, sunflower     

Effect of Oxygen on Photosynthetic 14CO2 Fixation in Chroomonas sp. (Cryptophyta) II. Effects of Inhibitors, Uncouplers and an Artificial Electron Mediator on the Inhibition of 14CO2 Fixation by Anaerobiosis

In "air-grown" Chroomonas sp. cells, low concentrations of DCMU(less than 0.1 µM) could prevent the inhibition of ¹⁴CO₂fixation by anaerobiosis under light-saturating conditions (morethan 40 W.m^–2), with phenazine methosulfate showing asimilar effect. Antimycin A, carbonyl cyanide m-chlorophenylhydrazone(CCCP), and N,N'-dicyclohexylcarbodiimide strongly inhibitedanaerobic photosynthesis at concentrations which did not significantlyinhibit the rate under 2% O₂ at high light intensity (200 W.m^–2),although 0.2 µM CCCP stimulated the rate under 2% O₂ tosome extent. On the other hand, KCN inhibited the rate muchmore strongly under 2% O₂ than N₂, although it inhibited therate very strongly at concentrations above 5 µM both underN₂ and 2% O₂. These results suggest that the inhibition of photosynthetic¹⁴CO₂ fixation by anaerobiosis in this alga result from ATPdeficiency caused by over-reduction of electron carriers ofthe cyclic electron flow and that oxygen can prevent the over-reduction.Cyclic electron flow seems to be necessary to provide additionalATP for CO₂ reduction under anaerobic conditions, although itseems to be less necessary under aerobic conditions. (Received July 21, 1983; Accepted January 23, 1984)     

Effect of Salicylhydroxamic Acid on Respiration, Photosynthesis, and Peroxidase Activity in Various Plant Tissues

Earlier reports from our laboratory described salicylhydroxamicacid (SHAM) stimulation of O₂ uptake by expanded soybean leavesor older green cotyledons. This stimulation could not be interpretedin terms of engagement or capacity of the cytochrome and alternativerespiratory pathways. In this report, we tested the possibilitythat a soluble peroxidase, which can be easily eluted from soybeanleaves and cotyledons, might be responsible for SHAM stimulationin whole tissue. The peroxidase catalyzes oxidation of NADHby O₂, is strongly stimulated by SHAM and benzhydroxamic acid(BHAM) and inhibited by KCN, propyl gallate and gentisic acid.This peroxidase, however, does not seem to be responsible forSHAM-stimulated O₂ uptake in whole, green tissue. In our earlier work reporting SHAM-stimulated respiration ingreen tissue, the samples had not been shielded from room light(10–20 µmol photons m^–2.s^–1). In thisreport, we show that O²-uptake rates of controls measured indarkness were always greater than those measured in room light.SHAM stimulation was not observed in the dark or in tissue withoutchlorophyll. We also found that CO₂ uptake of whole leafletsin saturating light was completely inhibited by SHAM fed throughthe transpiration stream. SHAM, therefore, is a potent inhibitorof photosynthesis. We conclude that the SHAM-stimulated respirationof green tissues we reported earlier likely was due to verylow rates of photosynthesis occurring under room light. ³Present address: SANDOZ Ltd., Agrobiological Research Station,4108 Witterswil, Switzerland ⁴Present address: WTC 1A3, Weyerhaeuser Co., Tacoma, WA 98477,U.S.A. (Received June 23, 1989; Accepted October 20, 1989)     

Effect of Oxygen on Photosynthetic 14CO2 Fixation in Chroomonas sp. (Cryptophyta) I. Some Characteristics of the Oxygen Effect

The effect of oxygen on photosynthetic ¹⁴CO₂ fixation in theair-grown freshwater flagellate Chroomonas sp. (Cryptophyta)was studied. Considerable inhibition by anaerobiosis was observedonly under light-saturated conditions with no effect from theCO₂ concentration. This inhibition was reversed by 2% O₂. With,more than 2% O₂, the rate of ¹⁴CO₂ fixation was inhibited; 100%O₂ caused about 20% inhibition which could be reversed by 2%O₂. The degree of inhibition was only slightly higher at lowconcentrations (less than 0.43 mM NaHCO₃) than at high CO₂ concentrations,indicating that photorespiration is not a main cause of thisinhibition. Possible causes of the inhibitions by anaerobiosisand by oxygen are discussed. (Received June 29, 1983; Accepted January 23, 1984)     

Further Characteristics of Salt-Dependent Bicarbonate Use by the Seagrass Zostera muelleri

Millhouse, J. and Strother, S. 1987. Further characteristicsof salt-dependent bicarbonate use by the seagrass Zostera muelleri.—J.exp. Bot. 38: 1055–1068. The contribution of HCO^–₃to photosynthetic O₂ evolutionin the seagrass Zostera muelleri Irmisch ex Aschers. increasedwith increasing salinity of the bathing seawater when the inorganiccarbon concentration was kept constant. K_1/2 (seawater salts)for HCO^–₃ -dependent photosynthesis was 66% of seawatersalinity. Both short- and long-term pretreatment at low salinitiesstimulated photosynthesis in full strength seawater. Twentyfour hours pre-incubation of seagrass plants in 3·0 molm^–3 NaHCO₃ resulted in increased photosynthesis at allsalinities, apparently due to stimulation of HCO^–₃ use(K_1/2 (seawater salts) = 26%). V_max (HCO^–₃) was not affectedby low salinity pretreatment. The kinetics of HCO^–₃ stimulationby the major seawater cations was investigated. Ca²⁺ was themost effective cation with the highest V_max (HCO^–₃) andwith K_1/2(Ca²⁺) = 14 mol m^–3. Mg²⁺ was also very effectiveat less than 50 mol m^–3 but higher concentrations wereinhibitory. This inhibition cannot be accounted for solely byprecipitation of MgCO₃. Na⁺ and K⁺ were both capable of stimulatingHCO^–₃ use. Stimulation was in two distinct parts. Up to500 mol m^–3, both citrate and chloride salts gave similarresults (K_1/2(Na⁺) 81 mol m^–3, V_max(HCO^–₃) 0·26µmol O₂ mg^–1 chl min^–1), but use of citratesalts above 500 mol m^–2 caused a second stimulation ofHCO^–₃ use (K_1/2(Na⁺) 830 mol m^–3, V_max(HCO^–₃)0·68 µmol O₂ mg^–1 chl min^–1). V_max(HCO^–₃)for the second-phase Na⁺ or K⁺ stimulation was of the same orderas for Ca²⁺-stimulated HCO^–₃ use. To further characterizesalt-dependent HCO^–₃ use, the sensitivity of photosynthesisto Tris and TES buffers was investigated. The effects of Trisappear to be due to the action of Tris⁺ causing stimulationof HCO^–₃ -dependent photosynthesis in the absence of salt,but inhibition of HCO^–₃ use in saline media. TES has noeffect on photosynthesis. External carbonic anhydrase, althoughimplicated in salt-dependent HCO^–₃ use in Z. muelleri,could not be detected in whole leaves. Key words: Zostera muelleri, HCO^–₃ use, salinity     

Effects of Low Concentrations of Sulphur Dioxide on Net Photosynthesis and Dark Respiration of Vicia faba

Rates of net photosynthesis, P_N, and dark respiration of Viciafaba plants were measured in the laboratory in clean air andin air containing up to 175 parts 10^–9 (500 µg m^–3)SO₂. At all SO₂ concentrations exceeding 35 parts 10^–9,P_N was inhibited compared with clean air. At light saturation,the magnitude of inhibition depended on SO₂ concentration butat low irradiances the inhibition was independent of concentration.Dark respiration rates increased substantially, independentof concentration. When exposures continued for up to 3 days,P_N returned to clean air values about 1 h after fumigation ceased:dark respiration recovered after one photoperiod. There wereno visible injuries. Reviewing possible mechanisms responsible for the inhibitionof P_N, it is suggested that SO₂ competes with CO₂ for bindingsites in RuBP carboxylase. Analysis of resistance analoguesdemonstrates that SO₂ altered both stomatal and internal (residual)resistances. A model of crop photosynthesis shows the implications of theobserved responses for the growth of field crops in which plantsare assumed to respond like laboratory plants. Photosynthesisof the crop would be less sensitive than that of individualplants to SO₂ concentration. Daily dry matter accumulation ofhypothetical ‘polluted crops’ would be substantiallyless than clean air values but would vary relatively littlewith SO₂ concentration. It is concluded that physiological basesexist to account for observed reductions in growth of plantsat very low SO₂ concentrations, and that thresholds for plantresponses to SO₂ require reassessment.     

Inhibition of Nodule Development in Soybean by Nitrate or Reduced Nitrogen

Imsande, J. 1986. Inhibition of nodule development in soybeanby nitrate or reduced nitrogen.—J. exp. Bot. 37: 348–355. Nodulation of hydroponically grown soybean plants [Glycine max(L.) Merr.] is inhibited by continuous growth in the presenceof 4· mol m^–3 KNO₃ The presence of 4·0 molm^–3 ‘starter nitrate’ for 3-6 d during noduledevelopment, however, subsequently stimulates nodule dry weightaccumulation and nitrogenase activity. These stimulations occureven though 4· mol m^–3 nitrate temporarily delaysnodule development, i.e. the late steps of nodule developmentare reversibly inhibited by a short-term exposure to 4·0mol m^–3 nitrate. On the other hand, treatment with 4·0mol m^–3 nitrate in excess of 14 d significantly reducesnodule dry weight Thus, extended growth in the presence of 4·0mol m^–3 KNO₃ seems to block both early and late stepsof nodule development. Nodulation of hydroponically grown soybeansis also inhibited by continuous growth in the presence of 2·0mol m^–3 (NH₄)₂SO₄ This inhibition is not caused by acidityof the growth medium. On the other hand, nodule development6 d after inoculation with Rhizoblum japonicum is not delayedby a 7-d exposure to 2·0 mol m^–3 (NH₄)₂SO₄ butis partially inhibited by a prolonged exposure to (NH₄)₂SO₄Because repression of nodulation by 4·0 mol m^–3KNO₃ is more severe than that by 2·0 mol m^–3 (NH₄)₂SO₄and because ammonium taken up by the soybean plant is not activelyoxidized to nitrate, it is suggested that there are at leasttwo mechanisms by which nitrate utilization represses noduleformation in soybean. Key words: Glycine max, nitrogen, nitrogen fixation, nodulation     

Plasmalemma Transport of HCO-3 and OH- in Chara corallina: Inhibitory Effect of Ammonium Sulphate

The influence of (NH₄)₂SO₄ on ¹⁴C assimilation and cyclosisin internodal cells of Chara corallina was investigated. Severeinhibition of ¹⁴C assimilation was found at pH values above7·0, this inhibition being correlated with the exogenouslevel of NH3 rather than NH⁺₄. Cyclosis was also affected athigher concentrations of (NH₄)₂SO₄. This effect was similarlycorrelated with exogenous levels of NH₃. ¹⁴C assimilation was inhibited non-competitively by (NH₄)₂SO₄,the apparent Km being increased from 0·55 to 1·5mM. The results suggest that the site(s) of inhibition is locatedat the plasmalemma, rather than at the chloroplasts. (Evidencein support of in vivo uncoupling of photophosphorylation, bylow concentrations of (NH₄)₂SO₄, was not obtained). Significant perturbation of the OH^– efflux pattern wasobserved as the level of (NH₄)₂SO₄ was increased. Induced migrationof efflux sites indicates that NH₃ may interfere with the cellularmechanism that controls OH^– transport. Using a cell-segmentisolating chamber it was shown that (NH₄)₂SO₄ inhibited OH^–efflux rather than HCO^–₃ transport. This inhibitory effectwas readily reversible. These data are discussed in terms of a possible relationshipbetween the observe NH₄)²SO₄ stimulation of ³⁶Cl^– influxand the effect of this compound on ¹⁴C assimilation.     

Effects of NO2 and O3 Alone or in Combination on Kidney Bean Plants (Phaseolus vulgaris L.): Products of 13CO2 Assimilation Detected by 13C Nuclear Magnetic Resonance

The effect of exposure of kidney bean primary leaves to NO₂and O₃, alone or in combination, on the fate of ¹³CO₂ assimilatedby photosynthesis was examined by ¹³C-NMR. There were more than70 peaks appearing in the ¹³C-NMR spectra for substances extractedfrom leaves with 80% ethanol. The 16 relatively well resolvedpeaks corresponded to signals from three sugars, two organicacids and four amino acids. These signals were used to estimatepool sizes and ^l3C incorporation. Exposures to NO₂ and O₃ increased the amounts of sucrose andfructose, but not the incorporation of the ¹³C label during10 min photosynthesis from ¹³CO₂. This suggests the presenceof photo-synthetically inactive pools of sucrose and fructose.Amounts of glycine and serine, and ¹³C incorporation into them,were increased by the exposure to the pollutants. The incorporationof ¹³C into alanine was stimulated by exposure to NO₂, but notby exposure to O₃ alone. The present study shows that with only simple procedures ofsample preparations ¹³C-NMR provides information on the productsof photosynthesis in leaves stressed by the two air pollutants. Key words: NO₂, O₃, Phaseolus vulgaris, CO₂ assimilation, ¹³C-NMR     

Ammonia emission from young barley plants: influence of N source, light/dark cycles and inhibition of glutamine synthetase

Barley (Hordeum vulgare L. cv. Golf) plants were grown at twodifferent relative addition rates; 0.1 and 0.2 d^–1 ofnitrate. Three to five days before measurements started theplants were transferred to a nutrient solution with 2 mM nitrateor ammonium. The ammonium-grown plants showed increased ammoniumlevels in both shoots and roots and also increased ammoniumconcentrations in xylem sap. Ammonia emission measured in cuvettes connected to an automaticNH₃ monitor was close to zero for nitrate-grown plants but increasedto 0.59 and 0.88 nmol NH₃ m^–2 S^–1 for plants transferredto ammonium after growing at RA=0.2 and 0.1 d^–1, respectively.In darkness, NH₃ emission decreased together with photosynthesisand transpiration, but increased rapidly when the light wasturned on again. Addition of 0.5 mM methionine sulphoximine (MSO) to the plantscaused an almost complete inhibition of both root and shootglutamine synthetase (GS) activity after 24 h. Ammonia emissionincreased dramatically and photosynthesis and transpirationdecreased in both nitrate- and ammonium-grown plants as a resultof the GS inhibition. At the same time plant tissue and xylemsap ammonium concentrations increased, indicating the importanceof GS in controlling plant ammonium levels and thereby NH₃ emissionfrom the leaves. Key words: Hordeum vulgare, ammonia emission, ammonium, glutamine synthetase, nitrogen nutrition, photosynthesis, transpiration     

Light-Induced Changes in Cytosolic pH in Leaf Cells of Egeria densa: Measurements with pH-Sensitive Microelectrodes

Light-induced changes of cytosolic pH (pH_c) and the plasmalemmapotential (E_m) in dark-adapted leaf cells of the aquatic plant,Egeria densa were measured simultaneously with double-barreledpH-sensitive microelectrodes. Upon illumination, pH_c increasedtransiently and then decreased to a level that was lower thanthe original value, while the plasmalemma was greatly hyperpolarizedafter an initial small depolarization. DCMU inhibited the light-inducedchanges in both pH_c and E_m. DCMU acted without directly inhibitingthe electrogenic proton pump in the plasmalemma since a decreasein pH_c caused by treatment with butyrate (H⁺-loading) hyperpolarizedthe plasmalemma in DCMU-pretreated cells. N.N-Dicyclohexylcarbodiimide(DCCD) also inhibited the light-induced changes in both pH_cand E_m. This result may be explained by direct inhibition ofthe proton pump in the plasmalemma by DCCD since the decreasein pH_c caused by butyrate did not induce membrane hyperpolarizationin DCCD-treated leaf cells. Fusicoccin induced membrane hyperpolarizationand slight acidification of the cytosol. DCCD inhibited thefusicoccin-induced changes in both pH_c and E_m. The mechanismof the light-induced changes in pH_c is discussed in relationto activities of the proton pump in the plasmalemma and photosynthesis. (Received January 10, 1994; Accepted June 9, 1994)